Measuring apparatus



April 13, 1937. E. R. HART MEASURING APPARATUS Filed July 21, 19:54

2 Shets-Sheet l.

INVENTOR.

m mm M M W Y April 13, 1937. E. 'R. HART MEASURING APPARATUS 2 Sheets-Sheet 2 Filed July 21, 1934 INVENTOR.

ATTORNEY.

Patented A r. i3, 183'? STTES ATET MEASURING APPARATUS Application Juiy 21, 1934, Serial No. 735,390

16 Claims.

This invention relates to measuring devices and particularly to devices for measuring and indicating the lengths of pieces of material.

My invention is particularly adapted to meas- 5 uring and indicating the successive lengths of a rolled metal sheet as it goes through the successive passes of the rolling mill stand on which the sheet is produced, and, therefore, in connection with the means for adjusting the rolls, my inven- 10 tion relates to the predetermining of the gauge thickness of rolled metal sheets.

It is an object of my invention to provide an improved method and means for measuring or measuring and indicating the lengths of pieces of l3 material.

Another object is to provide an improved method and means for measuring successively the lengths of a succession of pieces of material and for integrating or integrating and indicating the 20 integration of the said lengths.

Another object is to provide an improved methd and means for predetermining the gauge thickness of 2. rolled sheet rolled by a plurality of passes through a roll stand, comprising improved means for successively measuring the lengths of the sheet at the successive roll passes.

Another object is to provide an improved measuring device of the relatively rotatable dial finger and dial type.

30 Another object is to provide an improved means for actuating measuring devices of the relatively rotatable dial finger and dial type.

Another object is to provide an improved means for actuating measuring devices having relatively movable dial or scale and pointer elements.

Other objects will be apparent to those skilled in the art to which my invention appertains.

My invention is fully disclosed in the following description taken in connection with the accomio panying drawings, in which:

Fig. 1 is aside elevational view illustrating diagrammatically a part of a sheet rolling mill, and illustrating diagrammatically an embodiment of my invention associated therewith; V

Fig. 2 is a top plan View of the diagrammatic showing of Fig. 1;

Fig. 3 is a front elevational view of an indicating mechanism embodying a part of my inven- 50 tion illustrated diagrammatically in Figs. 1 and 2 and drawn to a larger scale;

Fig. 4 is a longitudinal sectional view taken approximately from the plane 4- 1 of Fig. 3 and illustrating diagrammatically circuit connec- 55 tions and apparatus which may be employed therewith in the operation of the embodiment illustrated in Figs. 1 and 2;

-Fig. 5 is a fragmentary view-similar to a part of Fig. 4 drawn to a larger scale and with parts thereof in different positions;

Figs. 6, '7 and 8 are, respectively, fragmentary sectional views taken approximately from the planes 6-6, l! and 88 of Fig. 4; v

Fig. 9 is a view illustrating a modification which may be employed in connection with a part of the apparatus of Fig. 4; V

Fig. 10 is adiagrammatic View illustrating an application of my invention to uses other than those illustrated in Figs. 1 and 2.

In connection with Figs. 1 and 2and 3 to 8 inclusive, I have illustrated my invention as applied to the measuring of the lengths of rolled metal sheets as the sheets pass through the rolls of the mill producing them, upon successive passes thereof. As a part of the embodiment of my invention, apparatus to be described is provided to automatically indicate the length of the sheet after each pass and to indicate the increase of length of the sheet caused by each successive pass through the rolls. By means of this indication, in connection with means conveniently operated by the mill operator, for adjusting the mill rolls, as the rolling process proceeds pass after pass, the'operator is able to produce sheets from the mill having the desired gauge thickness to a greater degree of accuracy than has heretofore been possible and more easily and efficiently.

In the greatly simplified diagrammatic apparatus of Fig. 1, I have shown at I and 2 mill tables and between the tables lower and upper rolls mounted in a stand 5, connected together to be driven in unison by means not shown, and the lower roll being driven from a shaft 6 connected to a source of power such as a steam engine or electric motor. Screw-down apparatus for raising or lowering the upper roll 4 adjustably is provided comprising beveled gears 'l--'l connected to bearing adjusting screws, not shown, pinions 8-8 meshed with the beveled gears 7 connected by a common shaft 9 adapted to be turned by a large diameter hand wheel I0.

By the means thus diagrammatically illus-, trated and described, and which means is well known in this art, upon turning the hand wheel iii, the upper roll i may be raised or lowered and will thereby correspondingly adjust. the thickness of a sheet or pack of sheets being rolled between the rolls. a

At 5 I is indicated a furnace in which sheet bars 12 may be heated preparatory to rolling them.

Indicated generally at l3 and I4 are so-called flag switches comprising each an arm |5 projecting upwardly through a suitable perforation or opening in the tables I and 2 and adapted to be operated to close a pair of contacts by engagement with the forward or leading edge of a sheet bar or sheet moving over the table toward the right (as viewed in the drawings) and to permit the contacts to be opened after the bar or sheet has passed over the arm. These switches are reproduced to a larger scale in Fig. 4 and their construction and operation will be more fully described in connection therewith.

At Fig. 2, is illustrated an electric generator, preferably single-phase, driven by a belt |8 on a small pulley 9 on the shaft of the generator, and a large pulley 20 on the roll shaft 6. The pulley 20 may, if preferred, be driven from any part of the motor or engine driving the rolls which ro-- tates at a speed the same as or proportional to the speed at which the rolls are driven.

At 2| generally is indicated an indicating mechanism to be described, preferably housed in a housing 22 supported on a pedestal 23 having an indicating dial 24 disposed to be conveniently visible by the operator who controls the hand wheel l0 above described. The indicator 2| will now be described.

Referring to Figs. 4 and 5, the indicator mechanism is housed in the housing 22,. the latter comprising a base 25, a rear wall 26, a generally hoodform cover 21 and a front panel 28. These parts may be held together in any suitable manner but preferably the cover 28 is detachably connected to the base 25, for example by screws 21, Fig. 3, whereby it may be removed to give access to the parts thereunder.

' A shelf 29 is rigidly supported in the housing and an electric motor 3|] of the synchronous type and preferably single phase is secured to and supported on'the shelf 29. The motor drives a pinion 3| through a reduction gearing indicated at 32 which may be of the worm-and-gear type to provide a relatively great reduction ratio. A frame comprising uprights 33- -31 is supported on the shelf 29 and the uprights 33 and 31 are clamped on opposite ends of a large diameter tube 34 by a through bolt 35 and nuts 3636. A plurality of such bolts may be provided. A bearing bushing 38 is projected through a suitable perforation in the upright 31 and a shaft 39 is rotatably supported therein. A suitable collar 49 prevents shifting of the shaft outwardly and a gear 4| prevents shifting in the other direction, the gear 4| being disposed to mesh with the pinion 3|. A second bushing 42, axially aligned with the bushing 38, projects through the upright 33 and a shaft 43 is rotatably supported therein. The inner ends of the shaft 39 and 43 are provided respectively with heads 44 and 45 having confronting planar faces and a friction disc 46 may be secured to one of the heads.

The heads 44 and 45, shafts 39 and 43, uprights 33 and 31, and the tube 34 are preferably formed from ferrous or magnetic material, and an electro-magnetic winding 4'! is disposed within the tube 34 surrounding the heads 44 and 45. The construction just described constitutes an electro-magnetic clutch. Upon energization of the winding 4'|, the heads 44 and 45 will be frictionally engaged with each other and rotation of the shaft 39 will be transmitted to the shaft 43 in a well known manner. The shaft 43 has thereon, spaced from the upright 33, a head 48 comprising a shank 49 and a flange 50. The head 48 is rigidly secured to the shaft with the flange 59 spaced from the upright 33. A compression spring of the helical type, 51, is telescoped over the shank 49 and the outwardly projecting portion of the bushing 42, abutting at opposite ends respectively upon the flange 50 and the upright 33, exerting a thrust toward the left as viewed in the drawings on the shaft 43 to normally disengage the heads 44 and45 when the winding 41 is de-energized.

: The inner end of the spring 5| extends downwardly below the shaft 43 and overlaps the side of a pin 52 projecting from the upright 33 (see Fig. 6), and overlaps the side of a pin 53 above the pin 52 projecting inwardly from the flange 59; and the other end of the spring 5| is correspondingly disposed to overlap the opposite sides of these pins. The spring 5| may thus have initial tension therein tending to unwind but restrained therefrom by the said pins.

' By this construction it will be apparent that when the shaft 43 is rotated by the motor 3 through the pinion 3|, gear 4| and clutch heads 44 and 45, which rotation is predetermined to be "counter-clockwise as viewed in Fig. 6, the head 58 will be rotated against the tension of the spring 52, tending always to return it to a normal position determined as indicated in Fig. 6.

Thus, with the motor 39 constantly running, upon energizing the winding 4? to energize the clutch heads 45 and 45, the head 48 will begin to rotate and upon de-energizing the winding 47 to de-energize the clutch heads, the head 43 willinstantly return to its original normal position.

A bracket 54 is secured to the upright 33 and has mounted thereon a bearing bushing 55 preferably disposed coaxial of the shaft 43, and a shaft 55 is rotatably supported therein. On the inner end of the shaft 55 and inwardly of the bearing bushing 55, a pin 5'! is provided extending substantially radially from the shaft 55 and is disposed to normally overlap a pin 53 extending outwardly axially from the flange 55 of the head 48 at a suitable distance from the axis of the shaft 43. On the outer end of the shaft 56 is provided a head 59 rigidly secured thereto. A ratchet wheel 50 is secured to the head 59. A pin 5! projects outwardly from the bracket 54 under the bushing 55; and a pin 52 projects inwardly from the head 59, and a helical spring 63 is telescoped over the bushing 55, the inner end thereof being extended downwardly to overlap the pins 5| and 82 on one side thereof, and the outer end extending downwardly to overlap the pins on the other side thereof, thus determining a normal rotative position for the head 59 and ratchet wheel 69 thereon.

The pins 58 and 51 are preferably so disposed that they will just engage each other when the heads 48 and 59 are .in their normal positions above described.

A ratchet pawl 64 is pivoted as at 55 upon a post 66 projecting from the bracket 54, the pawl engaging the teeth of the ratchet wheel 55, being normally retained in engagement with the teeth by the weight of a tail piece 5'! of the pawl on the opposite side of the pivot 55 from the pawl tooth.

An electro-magnetic trip device for the pawl 64 is provided supported upon the bracket 54 and generally depending therefrom. and comprises a magnetic frame 58 secured to the bracket 54, supporting a winding 69 and having a core piece 10 projecting into the winding. An armature H is pivoted to the frame 68 as at 72 and has a pole piece 13 adapted to be drawn upwardly into the winding 69 when energized. The armature 1I carries a finger 14 in the end of which is an adjustable screw 15 adapted to engage the tail piece 61 of the pawl 64 when the armature H is rocked around its pivot 12. The armature 1! has a de-energized position determined by an adjustable screw 16 upon which it normally rests, the screw being supported on the frame 68.

The front panel 28 has a circular disc 11 of cleartransparent glass or other suitable material mounted thereon, and at the center thereof on the outside of the glass is secured an opaque preferably white disc 18, thus providing an annular transparent portion 19. An outer annular portion of the disc 11, as at I21, may be frosted or otherwise rendered translucent if desired.

A dial finger is secured to the ratchet wheel 60 and has on its outer end an indicating head ill of any suitable form but preferably. of conventional diamond form with the points vertically opposite. The dial finger 80 is preferably formed from wire as shown in Fig. 3 to render it substantially invisible and the indicating head is preferably formed from fiat sheet metal and is disposed to move through the annular transverse portion 19, when viewed from outside upon movement of the ratchet wheel 60.

A short shaft 32, Figs. 4 and 5, is projected through a central perforation in the glass disc 11 and is secured in position by a flange 83 thereon on one side of the glass and a nut 84 on the other side. Projecting outwardly from the glass, the shaft has stepped shoulders thereon over each of which is telescoped a perforated sheet metal dial finger, three preferably being employed as shown at 85, 86 and 81. Friction washer 8888 may be provided on the outer side of each dial finger; and a nut 89 and washer 90 on the outer end of the shaft 82, by clamping the friction washers against the dial fingers, support the dial fingers rotatively on the shaft 82 and with each dial finger independently maintained in any rotated position. The dial fingers are preferably provided at their outer ends with pointer portions 9I-9I adjacent the periphery of the opaque disc 18. In Fig. 3 these dial fingers are illustrated in different positions around the disc 18 but in Fig. 5, in order to better illustrate the same, they have all been rotated to a common or superimposed position.

As illustrated in Fig. 4, in the diagram of connections associated therewith, the motor 30 is electrically connected to be driven by current from the generator I1 which, as described in connection with Fig. 2, is driven at a rate proportional to the speed of the rolls of the mill. The motor 30 is preferably, as stated, a synchronous motor and is self-starting. Thus the motor 30 will at all times be rotatively driven at the speed of the generator I1 and therefore at a speed at all times proportional to the speed of the mill rolls. The wires 92 and 93 connecting the generator to the motor are shown both in Figs. 2 and 4.

Referring to Fig. 4 in connection with Figs. 1 and 2, the fiag switches I3 and I4 are reproduced together with the diagrammatic wiring connections therewith. The flag switch I3 is illustrated associated with and mounted upon a fragment of the table I and comprises a supporting frame 94 on the table to which the switch arm I5 is pivotally connected below the table. A spring 95 normally holds the arm I5 upright by holding an extension 96 of the arm I5 below the pivot 91 against an abutment 98 on the frame 94. A pair of arcuate contacts 99and I00 are disposed to be electrically connected together by the arm extension 96 when the arm I5 is rocked clockwise as viewed in the figure.

The flag switch I4, associated with a fragment 1 of the table 2, may be identical with the switch I3, and the arm I6 thereof when rocked may cause an extension I M thereof to electrically connect a pair of arcuate contacts I02 and I03.

In the operation of the apparatus above described, it is assumed that sheet bars are heated in the furnace II, Figs. 1 and 2, and as in well known practice a sheet bar such as that shown at I2a is taken from the furnace and placed on the table I and progressively moved thereover toward the rolls 3 and 4. The forward end of the sheet bar will engage the arm I5 of the switch I3 and rock the same to close the contacts 99I00 and as the bar proceeds to the position I 2b, it will pass over the arm I5 which will be restored and disconnect the contacts 99-I09, thus the contacts being only momentarily closed.

The momentary closure of these contacts will cause current to flow, (see Fig. 4) from a current supply main I04 by a wire I05 to the con-,

tact I00, thence through the arm extension 96 to the contact 99 and thence by wire I06 to and through the winding 69, and by wire I01 back to the other supply main I00. Energization of the winding 69 will attract the armature II and cause the screw 15, (see Fig. 3), to engage the tail piece 61 of the ratchet 64 and disengage it from the ratchet wheel 60. Thereupon, the ratchet wheel and shaft 56 now being free to rotate, will be rotated by the spring 63 to restore the indicating head 8| to its neutral position indicated in Figs. 3 and 4.

After the sheet bar has passed beyond the switch I3, the contacts will be opened as described and the winding 69 accordingly de-energized and the pawl 64 will engage the ratchet wheel and thereafter will ratchet thereover in a manner to be described.

The operator of the mill will by this time have turned the hand wheel I0 to set the two rolls 3 and 4 to a suitable distance apart for the first pass of the sheet bar I2 'therethrough. As the sheet bar passes through the rolls, its leading edge will operate the switch I4 by engaging the arm I 6 thereof and rocking it to cause the extension I M to close or engage the contacts I02-I03 (see Fig. 4). Thereupon, current will flow from the supply main I04 by wire I99 to and through the clutch winding 41 and back by wire I I0 to the contact I02, through the connecting extension IOI, to contact I03 and thence back to the other supply'main I08.

Energization of the winding 41 will cause the clutch head 45 to be drawn magnetically into frictional engagement with the head 44. The mill rolls 3 and 4, of course, being at this time rotating from power supplied thereto, the generator I1, Figs. 1 and 2, is likewise being driven inasmuch as, as above described, it is connected to the source of power for the rolls; and inasmuch as the synchronous motor 33 is at all times connected to the generator I1, it likewise is running at the predetermined speed which is at all times precisely proportional to the speed of the rolls. Therefore, when the clutch heads 44 and 45 are engaged magnetically as just described, the motor 30, driving the shaft 39 through the pinion 3i and gear 4|, will drive the shaft 43. The pin 58 on the'head 46 connected to the shaft 43 will pick up the pin 51 and thereby rotate the shaft 56, and through the shaft will rotate the ratchetwheel 50 and the dial finger 89 and indicating head 8i thereon.

Thus, the indicating head 8| will move around the annular clear glass portion 19 of the front panel 28 of the device, Figs. 3 and 1, and the operator who may be standing near the hand wheel 19, Fig; 2, may observe and follow the movement of the indicating head 8i. From the foregoing description it will be apparent that the indicating head 81 will move at a predetermined velocity proportional to the rotational speed of the rolls 3 and 4.

When the sheet bar 12, Fig, 1, has passed entirely through the rolls 3 and 4 on the first pass, the sheet, in the position l2c, will pass over the switch M allowing the arm 5 to return to its upright position thereby breaking contact at lot-E93, correspondingly de-energizing the clutching winding 41. This de-energizes the clutch heads 44 and 45 and thereupon the spring 5! will return the headAB to its original position, which with the parts shown as in Fig. 4, will be with the pin 58 vertically above the axis of rotation. The shaft 56 and the pin 51 will, however, remain in their rotated position against the tension of the spring 63 tending to return these parts to their original position due to the engagement of the pawl 64 with the ratchet wheel 69.

Movement of the indicating head 8!, Figs. 1 and 3, thus is initiated at one end of the rolled sheet Ho and is stopped at the other end thereof so that the amount of its movement from its initial position Fig. 3 is a measure of the length of the sheet on the first pass.

It may be assumed at this time that the sheet bar now going through the mill is alsample bar.

of accurately known dimensions as to length and cross-section and may be used to calibrate, so to speak, the indicating instrument for the measurement of sheets rolled from successive sheet bars. In this'connection, when the indicating head 8| has come to rest as above described, for example in the position IH, Fig. 3, one of the dial fingers such as the finger may be rotated by the operator manually around to a position registering with the position III as indicated in Fig. 3, the dial finger 85 therefore indicating a suitable length for the sheet on the first pass.

The catcher at the mill now passes the sheet l2c back over the top of the upper roll 4 from the table 2 to the table I and it is ready to go through the rolls on the second pass. During this time the operator or roller turns the wheel it to'lower the roll 4 a suitable distance determined by experience. The sheet then goes throiigh the rolls and on the second pass again operates the switch Hi, again re-engaging the clutch heads 44 and 45, Fig. 4, and causing the pin 53 to begin rotating with the shaft 33. As Will be understood, the dial head 8| will remain stationary in its position H l until the pin 58 has caught up with the pin 51 and then, because the sheet is longer on the second pass than on the first pass, the magnetic clutch will remain engaged for a longer time and the indicating head 8| will begin to move from the position H! around to a position such as that indicated at H2, Fig. 3, where it will stop when the trailing end of the sheet on the second pass releases the switch M. When this occurs, the pin 58 will again be returned to its original position.

The roller may now set another dial finger,

such as 86, to a position opposite the indicating head at 2" as indicating a suitable length for the sheet on the second pass.

With the apparatus under consideration it is contemplated that the sheet will be finished on the third pass, and it is therefore necessary that the upper roll must be screwed down by the hand wheel l0 to exactly the correct position in order that the gauge thickness of the sheet will be correct after the third pass. To accomplish this the roller must screw down the upper roll so that it will cause the sheet to have a precalculated length after the third pass. A third dial fingers 81 may beset to a position indicating the correct length of the finished sheet, and the roller may be guided by the distance between the dial fingers 86. and 81' to supplement his experience to enable him to accurately screw down the upper roll to its final or'third pass position.

The sheet is then run through the rolls on V the third pass and the indicating head is thereby after each of the first two passes, the operator or roller can by observing the position of the indicating head know exactly the length of the sheet and therefore can more accurately screw down the upper roll for the next pass to cause the third pass to produce the desired length of sheet and therefore the desired thickness gauge.

In other words, after each pass, the mill roller,

by observing the position of the indicating head Bl, can observe instantly the length of the sheet produced by that pass and therefore know its gauge thickness on that pass and be guided thereby to screw down the roll for the next pass, and

thus can continuously produce sheets to a far higher degree of accuracy of gauge thickness than has heretofore been possible.

When the sheet isfinished and is'carried away on the table 2 and another sheet bar is moved onto the table I, the switch I5 will be operated I as above described to trip the ratchet wheel 60 and thereupon the indicating head 8| will be moved back to its original position. If desired, the ratchet may be tripped by the finished sheet, and for this purpose an optional switch, indicated generally at H4, Figs. 1, 2 and 4, may be provided, similar or identical to the switches l3 and I4 and connected as shown in Fig. 4 in parallel with the contacts 99 and I00 of the switch l3 whereby the finished sheet in passing thereover will momentarily energize the ratchet trip winding 69 just as this operation was described as being performed for the switch l3. Thus, either or both of the switches H4 or l3 may be employed to re-set the indicator dial head 8|.

The apparatus above described is entirely automatic for the rolling of successive sheet bars into sheets, automatically indicating the increase of lengths of the sheets on each pass and automatically integrating the length increases to indicate the total lengths of the sheets after each pass; and automatically re-setting after the sheets have been finished.

While I have described, in the above, the operation of the apparatus as rolling a single sheet,

it will be understood that its operation will be the same where sheets are rolled in packs by the well known processes.

Again, while I have shown the indicating head 8| as at the top of the dial at its starting point, it Will of course be obvious that it may be at the bottom or at any other point around the circle if desired.

The dials may be made as large as desired to make them readily visible at any desired distance from the position at which the mill roller may stand. To further facilitate visibility, the dial fingers 85, 80 and 8'3 may be of a dark color or black and the opaque disc l8 may be white. As stated above, the indicating head 8I may be black, and to render it more readily visible, a white or light-colored back-ground disc I I5, Fig. 4, may be provided supported upon the uprights 33 and 31 by suitable studs or the like I iii. A lamp or a plurality of lamps II I may be mounted within the instriunent housing 22 energized in any suitable manner from the supply mains I and I08 and disposed to illuminate the forward face of the background II 5 and concealed from view through the transparent annular portion I9 of the panel. Furthermore, the disc '58 may be large enough in diameter to conceal parts of the mechanism therebehind to avoid visual confusion.

As is well known in the sheet rolling art, the mill rolls are from time to time re-dressed which reduces them in diameter. The smaller rolls, however, may be driven at the same rotational velocity and therefore the indicating head 8| will move with the same velocity, but the rolls will make more revolutions for a given length of sheet and therefore the indicating head in its successive positions will indicate a greater length for a given length of sheet coming from the smaller rolls than it would indicate for the same length of sheet on the larger rolls. This difference may be ignored because the dial may be calibrated on the first run to correspond to the smaller rolls.

If, however, it be desired that the movements of the indicating head 8I shall at all times indicate absolute lengths of sheet, the arrangement indicated diagrammatically in Fig. 9 may be employed. Instead of the pinions 3I and II of Fig. 4, the tapered pulleys 3IA and 4IA may be provided; and instead of direct gear tooth connection as in Fig. 4, the pulleys may be connected by a belt H8. A bracket or other base H9 may be supported within the housing 22 on any suitable support to mount a belt shifting device comprising a stationary nut I20 having a hand wheel IZI for turning it and a longitudinally movable screw I22 provided at one end with a fork I23 engaging opposite sides of the belt H8, and on the other end provided with a point er I24 movable over a scale I25.

As will be apparent, upon turning the wheel I2I, the belt II8 will be shifted longitudinally of the tapered pulleys 3IA and MA to change the ratio of speed reduction effected thereby to correct for the change of roll diameter, and the scale I25 may be calibrated in diameters of the driven roll. Thus, for any diameter of rolls, upon correspondingly setting the dial finger I20 by turning the hand wheel I2I, a ratio of velocities will be established to cause the indicating head 8| always to move the same distance for the same length of sheet.

In Fig. 10, I have illustrated diagrammatically the application of my invention to another use, namely that of measuring and indicating the length of a wire or ribbon or sheet or any other material which may be passed between rolls. In the embodiment illustrated in Fig. 10, the material is in the form of a roll 200 and may be mounted to rotate on a support 20I. The end of the material 202 is inserted between a pair of rolls 203 and 204 gripping the material therebetween. A single phase generator 205 is belted to one of the rolls as by a belt 206 and suitable pulleys 207 and 208 and supply lines 209 and 2I0 are led from the generator to the hous ing 22 above described in which may be provided the same mechanism as that above described. A switch shown generally at 2I I is provided which may be identical with the switch I 4 above described and disposed opposite .the beginning end of the material 202.

Contacts I02 and I03 of the switch 2 may be connected to the indicating device 2| and tothe line the same as are the contacts I02 and I03 of the switch I l. A manual switch having contacts 09 and I00 may be connected to the line and to the indicator 2| as are the contacts 99 and I00 of the switch l3.

The contacts 99 and M0 may be momentarily closed to re-set the indicator. Then the end 202 of the material may be drawn through the rolls 203-204 operating the switch 2 to close its contacts and hold them closed, thereby starting movement of the indicating head 8|, the generator 205 being operated to generate current by power received from the rotating roll 203 which in turn is rotated by the material 202 passing thereover. If the material is drawn faster at one time than another, it will correspondingly increase the frequency of the generator 205 and the synchronous motor in the indicating apparatus 2I will correspondingly rotate faster so that at all times the indicating head 8| will move at a rate proportional to the rate at which the material 202 moves through the rolls. The distance around the circle of the indicating head al from its starting point will at all times indicate the length of the material which has passed through the roll, and obviously any reductionratio between the motor in the device 2| and the indi-' cating head 8| may be provided so that suitably great lengths or short lengths of material 20I may be indicated on a single revolution of the indicating head 8|; or, in the case of great lengths of material, the revolutions of the indicating head 8| may be counted visually.

It will therefore be apparent that my invention is not limited to the rolling of sheets in a rolling mill, although this is one of its more important uses.

In some applications of my invention, it may be desirable to have the indicating head 8| indicate lengths of material in units, for example inches,'and for this purpose the disc 9I may have a scale thereon, a fragment of which is indicated at I20, Fig. 3.

My invention is not limited to the exact details of construction shown and described. Other modifications and changes may be made within the spirit of my invention and within the scope of the appended claims.

I claim:

1. In an apparatus for measuring the lengths of pieces of material, a rotatable element having a peripheral portion frictionally engageable with a generally relatively tangentially moving piece to be measured, an electric generator, and means to drive it at speeds constantly proportional to the speed of the rotatable element, an electric iii motor electrically driven by the generator at speeds constantly proportional to the generator speed, an indicator comprising a movable element driven by the motor, a clutch device operable to efiect driving connection and disconnection of the motor with the indicator movable element, means operable by the movement of the piece to efiect said clutch operations, and means for holding the movable indicating element in an indicating position after disengagement of the clutch, and means operable by movement of the piece to return the indicating element to a starting position.

2. In an apparatus for measuring the lengths of pieces of material, a rotatable element having a peripheral portion frictionally engageable with a generally relatively tangentially moving piece to be measured, an electric generator, means for driving it at speeds constantly proportional to the speed of the rotatable element, an electric motor electrically driven by the generator at speeds constantly proportional to the generator speed, an indicator comprising a movable element drivable by the motor, means to effect starting and stopping movement of the indicating element comprising means engageable by leading and trailing end portions of the piece, means tending to return the movable indicating element to a starting position, holding means to hold the movable indicating element in an indicating position after disengagement of the clutch, and releasing means operable by movement of the piece to release the holding means.

3. In an apparatus for measuring the lengths of pieces of material, a rotatable element having a peripheral portion frictionally engageable with a generally relatively tangentially moving piece to be measured, an electric generator, and means to drive it at speeds constantly proportional to the speed of the rotatable element, an electric motor electrically driven by the generator at speeds constantly proportional tothe generator speed, an indicator comprising a movable element drivable by the motor, means tending to return the movable indicating element to a starting position, holding means to hold the movable indicating element in an indicating position after disengagement of the clutch, and releasing means operable by movement of the piece to release the holding means.

4. In an indicating apparatus, a movable indicating element having a normal starting position, a movable power transmitting element having a normal starting position for moving the indicating element to indicating positions, restoring means tending to return the transmitting element to its starting position, holding means for holding the indicating element in indicating positions, a source of power for moving the transmitting element, and means to intermittently apply power from the source to the transmitting element to cause it to intermittently move the indicating element to successive positions and, between applications of power, to permit the restoring means to return the transmitting element to starting position.

5. In an indicating apparatus, a movable indicating element having a normal starting position, a movable power transmitting element having a normal starting position for moving the indicating element to indicating positions, restoring means and returning means respectively tending to restore the indicating element and return the transmitting element to their starting positions, holding means for holding the indicating element inindicating positions, a source of power for moving the transmitting element, and means to intermittently apply power from the source to the transmitting element to cause it to intermittently move the indicating element to successive positions and between applications of power, to permit the returning means to return the transmitting element to starting position, and releasing means for releasing the holding means to permit the restoring means to restore the indicating element to starting position.

6. An indicating apparatus as described in claim 4 and in which the power source is a continu-- ously operating electric motor and the means to intermittently apply power to the transmitting element is a clutch device.

'7. An indicating apparatus as described in claim 4 and in which the power source is a continuously operating electric motor and the means to intermittently apply power to the transmitting element is an electro-magnetically operable clutch device.

8. An indicating apparatus as described in claim 5 and in which the holding means for holding the indicating element is a pawl and ratchet device and the releasing means is an electro-magnetic trip device therefor.

9. In an apparatus for indicating the length of a metal sheet rolled by successive passes between the rolls of a mill, an indicating apparatus comprising a movable indicating element having a starting position, means for moving the indicating element from the starting position at a speed proportional to the sheet velocity, means effective on said indicating element continuously tending to return it to the starting position, means responsive to movement of the sheet to effect movement of the indicating element an amount proportional to the length of the rolled sheet on the first pass, and to effect movement of the indicating element amounts proportional to the increases of length of the sheet on succeeding passes, whereby the final position of the indicating element may indicate the final length of the sheet, and means holding said indicating element in each said indicating position and means to disable the holding means after the last pass.

10. An apparatus as described in claim 9 and in which means is provided responsive to sheet movement after the last pass to effect return of the indicating element to the starting position.

11. In an apparatus for indicating the length of a metal sheet rolled from a sheet bar by successive passes between the rolls of a mill, an indicator comprising a movable indicating element having a starting position, means for moving the indicating element from the starting position at a speed proportional to the sheet velocity through the rolls, means responsive to movement of the sheet to efiect movement of the indicating element an amount proportional to the length of the rolled sheet on the first pass, and to effect movement of the indicating element amounts proportional to the increases of length of the sheet on successive passes whereby the final position of the indicating element may indicate the final length of the sheet, and means responsive to movement of a succeeding sheet bar prior to the first pass thereof to effect return of the indicating element to the starting position.

12. In an apparatus for indicating the length of a metal sheet rolled by successive passes of a sheet bar between the rolls of a mill, an indicator comprising a movable indicating element having a starting position, means for moving the indieating element from the starting position to successive positions at speeds proportional to the sheet velocity, means for holding the indicating element in successive positions, said moving means comprising a continuously operable source of power at roll velocity, a power transmitting element having a starting position and movable therefrom by the power source to move the indicating element, restoring means tending to return the transmitting element to its starting position, means responsive to movement of the sheet through each pass to efiect corresponding intermittent application of power from the source to move the transmitting element an amount proportional to the length of the sheet and after each application of power to permit the restoring means to return the transmitting element to starting position to cause it to move the indicating element to successive positions successively farther from the starting position whereby each position of the indicating element may indicate the total length of the sheet effected by preceding passes, and the movement of the indicating element from each position tothe next may indicate 5 the increment of sheet length of the preceding pass.

13. An apparatus as described in claim 12. and in which means is provided operable to effect return of the indicating element to starting position 30 responsive to sheet movement after the last pass.

14. An apparatus as described in claim 12 and in which means is provided operable to efiect return of the indicating element to the starting position after the last sheet pass responsive to movement of a succeeding sheet bar prior to the first pass thereof.

15. In an apparatus for measuring the lengths of pieces of material, a rotatable element having a peripheral portion frictionally engageable with a generally tangentially moving piece to be meas ured, a movable length indicating element having a normal starting position, a movable power transmitting element having a normal starting position for moving the indicating element to indicating positions, restoring means tending to return the transmitting element to its starting position, holding means for holding the indicating element in indicating positions, a source of power for moving the transmitting element, means causing the movement thereof to synchronize with movement of the rotatable element, and means to intermittently apply power from the source to the transmitting element to cause it to intermittently move the indicating element to successive positions, and between applications of power, to permit the restoring means to return the transmitting element to starting position.

16. The indicating apparatus described in claim 4 and in which means is provided operable to return the indicating element to its normal position.

EARL R. HART. 

